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llvm-project/lldb/source/Interpreter/ScriptInterpreterPython.cpp

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//===-- ScriptInterpreterPython.cpp -----------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// In order to guarantee correct working with Python, Python.h *MUST* be
// the *FIRST* header file included in ScriptInterpreterPython.h, and that
// must be the *FIRST* header file included here.
#include "lldb/Interpreter/ScriptInterpreterPython.h"
#include <stdlib.h>
#include <stdio.h>
#include <string>
#include "lldb/API/SBFrame.h"
#include "lldb/API/SBBreakpointLocation.h"
#include "lldb/Breakpoint/StoppointCallbackContext.h"
#include "lldb/Core/Debugger.h"
#include "lldb/Core/Timer.h"
#include "lldb/Host/Host.h"
#include "lldb/Interpreter/CommandInterpreter.h"
#include "lldb/Interpreter/CommandReturnObject.h"
#include "lldb/Target/Thread.h"
using namespace lldb;
using namespace lldb_private;
static ScriptInterpreter::SWIGInitCallback g_swig_init_callback = NULL;
static ScriptInterpreter::SWIGBreakpointCallbackFunction g_swig_breakpoint_callback = NULL;
static ScriptInterpreter::SWIGPythonTypeScriptCallbackFunction g_swig_typescript_callback = NULL;
static ScriptInterpreter::SWIGPythonCreateSyntheticProvider g_swig_synthetic_script = NULL;
static ScriptInterpreter::SWIGPythonCalculateNumChildren g_swig_calc_children = NULL;
static ScriptInterpreter::SWIGPythonGetChildAtIndex g_swig_get_child_index = NULL;
static ScriptInterpreter::SWIGPythonGetIndexOfChildWithName g_swig_get_index_child = NULL;
static ScriptInterpreter::SWIGPythonCastPyObjectToSBValue g_swig_cast_to_sbvalue = NULL;
static ScriptInterpreter::SWIGPythonUpdateSynthProviderInstance g_swig_update_provider = NULL;
static int
_check_and_flush (FILE *stream)
{
int prev_fail = ferror (stream);
return fflush (stream) || prev_fail ? EOF : 0;
}
static Predicate<lldb::tid_t> &
PythonMutexPredicate ()
{
static lldb_private::Predicate<lldb::tid_t> g_interpreter_is_running (LLDB_INVALID_THREAD_ID);
return g_interpreter_is_running;
}
static bool
CurrentThreadHasPythonLock ()
{
TimeValue timeout;
timeout = TimeValue::Now(); // Don't wait any time.
return PythonMutexPredicate().WaitForValueEqualTo (Host::GetCurrentThreadID(), &timeout, NULL);
}
static bool
GetPythonLock (uint32_t seconds_to_wait)
{
TimeValue timeout;
if (seconds_to_wait != UINT32_MAX)
{
timeout = TimeValue::Now();
timeout.OffsetWithSeconds (seconds_to_wait);
}
return PythonMutexPredicate().WaitForValueEqualToAndSetValueTo (LLDB_INVALID_THREAD_ID,
Host::GetCurrentThreadID(), &timeout, NULL);
}
static void
ReleasePythonLock ()
{
PythonMutexPredicate().SetValue (LLDB_INVALID_THREAD_ID, eBroadcastAlways);
}
ScriptInterpreterPython::ScriptInterpreterPython (CommandInterpreter &interpreter) :
ScriptInterpreter (interpreter, eScriptLanguagePython),
m_embedded_python_pty (),
m_embedded_thread_input_reader_sp (),
m_dbg_stdout (interpreter.GetDebugger().GetOutputFile().GetStream()),
m_new_sysout (NULL),
m_dictionary_name (interpreter.GetDebugger().GetInstanceName().AsCString()),
m_terminal_state (),
m_session_is_active (false),
m_pty_slave_is_open (false),
m_valid_session (true)
{
static int g_initialized = false;
if (!g_initialized)
{
g_initialized = true;
ScriptInterpreterPython::InitializePrivate ();
}
bool safe_to_run = false;
bool need_to_release_lock = true;
int interval = 5; // Number of seconds to try getting the Python lock before timing out.
// We don't dare exit this function without finishing setting up the script interpreter, so we must wait until
// we can get the Python lock.
if (CurrentThreadHasPythonLock())
{
safe_to_run = true;
need_to_release_lock = false;
}
while (!safe_to_run)
{
safe_to_run = GetPythonLock (interval);
if (!safe_to_run)
{
FILE *tmp_fh = (m_dbg_stdout ? m_dbg_stdout : stdout);
fprintf (tmp_fh,
"Python interpreter is locked on another thread; "
"please release interpreter in order to continue.\n");
interval = interval * 2;
}
}
m_dictionary_name.append("_dict");
StreamString run_string;
run_string.Printf ("%s = dict()", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'import sys')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
// Importing 'lldb' module calls SBDebugger::Initialize, which calls Debugger::Initialize, which increments a
// global debugger ref-count; therefore we need to check the ref-count before and after importing lldb, and if the
// ref-count increased we need to call Debugger::Terminate here to decrement the ref-count so that when the final
// call to Debugger::Terminate is made, the ref-count has the correct value.
//
// Bonus question: Why doesn't the ref-count always increase? Because sometimes lldb has already been imported, in
// which case the code inside it, including the call to SBDebugger::Initialize(), does not get executed.
int old_count = Debugger::TestDebuggerRefCount();
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'import lldb')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
int new_count = Debugger::TestDebuggerRefCount();
if (new_count > old_count)
Debugger::Terminate();
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'import copy')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'lldb.debugger_unique_id = %d')", m_dictionary_name.c_str(),
interpreter.GetDebugger().GetID());
PyRun_SimpleString (run_string.GetData());
if (m_dbg_stdout != NULL)
{
m_new_sysout = PyFile_FromFile (m_dbg_stdout, (char *) "", (char *) "w", _check_and_flush);
}
if (need_to_release_lock)
ReleasePythonLock();
}
ScriptInterpreterPython::~ScriptInterpreterPython ()
{
Debugger &debugger = GetCommandInterpreter().GetDebugger();
if (m_embedded_thread_input_reader_sp.get() != NULL)
{
m_embedded_thread_input_reader_sp->SetIsDone (true);
m_embedded_python_pty.CloseSlaveFileDescriptor();
m_pty_slave_is_open = false;
const InputReaderSP reader_sp = m_embedded_thread_input_reader_sp;
m_embedded_thread_input_reader_sp.reset();
debugger.PopInputReader (reader_sp);
}
if (m_new_sysout)
{
FILE *tmp_fh = (m_dbg_stdout ? m_dbg_stdout : stdout);
if (!CurrentThreadHasPythonLock ())
{
while (!GetPythonLock (1))
fprintf (tmp_fh, "Python interpreter locked on another thread; waiting to acquire lock...\n");
Py_DECREF (m_new_sysout);
ReleasePythonLock ();
}
else
Py_DECREF (m_new_sysout);
}
}
void
ScriptInterpreterPython::ResetOutputFileHandle (FILE *fh)
{
if (fh == NULL)
return;
m_dbg_stdout = fh;
FILE *tmp_fh = (m_dbg_stdout ? m_dbg_stdout : stdout);
if (!CurrentThreadHasPythonLock ())
{
while (!GetPythonLock (1))
fprintf (tmp_fh, "Python interpreter locked on another thread; waiting to acquire lock...\n");
EnterSession ();
m_new_sysout = PyFile_FromFile (m_dbg_stdout, (char *) "", (char *) "w", _check_and_flush);
LeaveSession ();
ReleasePythonLock ();
}
else
{
EnterSession ();
m_new_sysout = PyFile_FromFile (m_dbg_stdout, (char *) "", (char *) "w", _check_and_flush);
LeaveSession ();
}
}
void
ScriptInterpreterPython::SaveTerminalState (int fd)
{
// Python mucks with the terminal state of STDIN. If we can possibly avoid
// this by setting the file handles up correctly prior to entering the
// interpreter we should. For now we save and restore the terminal state
// on the input file handle.
m_terminal_state.Save (fd, false);
}
void
ScriptInterpreterPython::RestoreTerminalState ()
{
// Python mucks with the terminal state of STDIN. If we can possibly avoid
// this by setting the file handles up correctly prior to entering the
// interpreter we should. For now we save and restore the terminal state
// on the input file handle.
m_terminal_state.Restore();
}
void
ScriptInterpreterPython::LeaveSession ()
{
m_session_is_active = false;
}
void
ScriptInterpreterPython::EnterSession ()
{
// If we have already entered the session, without having officially 'left' it, then there is no need to
// 'enter' it again.
if (m_session_is_active)
return;
m_session_is_active = true;
StreamString run_string;
run_string.Printf ("run_one_line (%s, 'lldb.debugger_unique_id = %d')", m_dictionary_name.c_str(),
GetCommandInterpreter().GetDebugger().GetID());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'lldb.debugger = lldb.SBDebugger.FindDebuggerWithID (%d)')",
m_dictionary_name.c_str(),
GetCommandInterpreter().GetDebugger().GetID());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
ExecutionContext exe_ctx = m_interpreter.GetDebugger().GetSelectedExecutionContext();
if (exe_ctx.target)
run_string.Printf ("run_one_line (%s, 'lldb.target = lldb.debugger.GetSelectedTarget()')",
m_dictionary_name.c_str());
else
run_string.Printf ("run_one_line (%s, 'lldb.target = None')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
if (exe_ctx.process)
run_string.Printf ("run_one_line (%s, 'lldb.process = lldb.target.GetProcess()')", m_dictionary_name.c_str());
else
run_string.Printf ("run_one_line (%s, 'lldb.process = None')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
if (exe_ctx.thread)
run_string.Printf ("run_one_line (%s, 'lldb.thread = lldb.process.GetSelectedThread ()')",
m_dictionary_name.c_str());
else
run_string.Printf ("run_one_line (%s, 'lldb.thread = None')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
if (exe_ctx.frame)
run_string.Printf ("run_one_line (%s, 'lldb.frame = lldb.thread.GetSelectedFrame ()')",
m_dictionary_name.c_str());
else
run_string.Printf ("run_one_line (%s, 'lldb.frame = None')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
PyObject *sysmod = PyImport_AddModule ("sys");
PyObject *sysdict = PyModule_GetDict (sysmod);
if ((m_new_sysout != NULL)
&& (sysmod != NULL)
&& (sysdict != NULL))
PyDict_SetItemString (sysdict, "stdout", m_new_sysout);
if (PyErr_Occurred())
PyErr_Clear ();
if (!m_pty_slave_is_open)
{
run_string.Clear();
run_string.Printf ("run_one_line (%s, \"new_stdin = open('%s', 'r')\")", m_dictionary_name.c_str(),
m_pty_slave_name.c_str());
PyRun_SimpleString (run_string.GetData());
m_pty_slave_is_open = true;
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'sys.stdin = new_stdin')", m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
}
}
bool
ScriptInterpreterPython::ExecuteOneLine (const char *command, CommandReturnObject *result)
{
if (!m_valid_session)
return false;
// We want to call run_one_line, passing in the dictionary and the command string. We cannot do this through
// PyRun_SimpleString here because the command string may contain escaped characters, and putting it inside
// another string to pass to PyRun_SimpleString messes up the escaping. So we use the following more complicated
// method to pass the command string directly down to Python.
bool need_to_release_lock = true;
if (CurrentThreadHasPythonLock())
need_to_release_lock = false;
else if (!GetPythonLock (1))
{
fprintf ((m_dbg_stdout ? m_dbg_stdout : stdout),
"Python interpreter is currently locked by another thread; unable to process command.\n");
return false;
}
EnterSession ();
bool success = false;
if (command)
{
// Find the correct script interpreter dictionary in the main module.
PyObject *main_mod = PyImport_AddModule ("__main__");
PyObject *script_interpreter_dict = NULL;
if (main_mod != NULL)
{
PyObject *main_dict = PyModule_GetDict (main_mod);
if ((main_dict != NULL)
&& PyDict_Check (main_dict))
{
// Go through the main dictionary looking for the correct python script interpreter dictionary
PyObject *key, *value;
Py_ssize_t pos = 0;
while (PyDict_Next (main_dict, &pos, &key, &value))
{
// We have stolen references to the key and value objects in the dictionary; we need to increment
// them now so that Python's garbage collector doesn't collect them out from under us.
Py_INCREF (key);
Py_INCREF (value);
if (strcmp (PyString_AsString (key), m_dictionary_name.c_str()) == 0)
{
script_interpreter_dict = value;
break;
}
}
}
if (script_interpreter_dict != NULL)
{
PyObject *pfunc = NULL;
PyObject *pmod = PyImport_AddModule ("embedded_interpreter");
if (pmod != NULL)
{
PyObject *pmod_dict = PyModule_GetDict (pmod);
if ((pmod_dict != NULL)
&& PyDict_Check (pmod_dict))
{
PyObject *key, *value;
Py_ssize_t pos = 0;
while (PyDict_Next (pmod_dict, &pos, &key, &value))
{
Py_INCREF (key);
Py_INCREF (value);
if (strcmp (PyString_AsString (key), "run_one_line") == 0)
{
pfunc = value;
break;
}
}
PyObject *string_arg = PyString_FromString (command);
if (pfunc && string_arg && PyCallable_Check (pfunc))
{
PyObject *pargs = PyTuple_New (2);
if (pargs != NULL)
{
PyTuple_SetItem (pargs, 0, script_interpreter_dict);
PyTuple_SetItem (pargs, 1, string_arg);
PyObject *pvalue = PyObject_CallObject (pfunc, pargs);
Py_DECREF (pargs);
if (pvalue != NULL)
{
Py_DECREF (pvalue);
success = true;
}
else if (PyErr_Occurred ())
{
PyErr_Print();
PyErr_Clear();
}
}
}
}
}
Py_INCREF (script_interpreter_dict);
}
}
LeaveSession ();
if (need_to_release_lock)
ReleasePythonLock();
if (success)
return true;
// The one-liner failed. Append the error message.
if (result)
result->AppendErrorWithFormat ("python failed attempting to evaluate '%s'\n", command);
return false;
}
LeaveSession ();
if (need_to_release_lock)
ReleasePythonLock ();
if (result)
result->AppendError ("empty command passed to python\n");
return false;
}
size_t
ScriptInterpreterPython::InputReaderCallback
(
void *baton,
InputReader &reader,
InputReaderAction notification,
const char *bytes,
size_t bytes_len
)
{
lldb::thread_t embedded_interpreter_thread;
LogSP log (lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_SCRIPT));
if (baton == NULL)
return 0;
ScriptInterpreterPython *script_interpreter = (ScriptInterpreterPython *) baton;
if (script_interpreter->m_script_lang != eScriptLanguagePython)
return 0;
StreamSP out_stream = reader.GetDebugger().GetAsyncOutputStream();
bool batch_mode = reader.GetDebugger().GetCommandInterpreter().GetBatchCommandMode();
switch (notification)
{
case eInputReaderActivate:
{
if (!batch_mode)
{
out_stream->Printf ("Python Interactive Interpreter. To exit, type 'quit()', 'exit()' or Ctrl-D.\n");
out_stream->Flush();
}
// Save terminal settings if we can
int input_fd = reader.GetDebugger().GetInputFile().GetDescriptor();
if (input_fd == File::kInvalidDescriptor)
input_fd = STDIN_FILENO;
script_interpreter->SaveTerminalState(input_fd);
if (!CurrentThreadHasPythonLock())
{
while (!GetPythonLock(1))
{
out_stream->Printf ("Python interpreter locked on another thread; waiting to acquire lock...\n");
out_stream->Flush();
}
script_interpreter->EnterSession ();
ReleasePythonLock();
}
else
script_interpreter->EnterSession ();
char error_str[1024];
if (script_interpreter->m_embedded_python_pty.OpenFirstAvailableMaster (O_RDWR|O_NOCTTY, error_str,
sizeof(error_str)))
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, Activate, succeeded in opening master pty (fd = %d).",
script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor());
embedded_interpreter_thread = Host::ThreadCreate ("<lldb.script-interpreter.embedded-python-loop>",
ScriptInterpreterPython::RunEmbeddedPythonInterpreter,
script_interpreter, NULL);
if (IS_VALID_LLDB_HOST_THREAD(embedded_interpreter_thread))
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, Activate, succeeded in creating thread (thread = %d)", embedded_interpreter_thread);
Error detach_error;
Host::ThreadDetach (embedded_interpreter_thread, &detach_error);
}
else
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, Activate, failed in creating thread");
reader.SetIsDone (true);
}
}
else
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, Activate, failed to open master pty ");
reader.SetIsDone (true);
}
}
break;
case eInputReaderDeactivate:
script_interpreter->LeaveSession ();
break;
case eInputReaderReactivate:
if (!CurrentThreadHasPythonLock())
{
while (!GetPythonLock(1))
{
// Wait until lock is acquired.
}
script_interpreter->EnterSession ();
ReleasePythonLock();
}
else
script_interpreter->EnterSession ();
break;
case eInputReaderAsynchronousOutputWritten:
break;
case eInputReaderInterrupt:
::write (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor(), "raise KeyboardInterrupt\n", 24);
break;
case eInputReaderEndOfFile:
::write (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor(), "quit()\n", 7);
break;
case eInputReaderGotToken:
if (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor() != -1)
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, GotToken, bytes='%s', byte_len = %d", bytes,
bytes_len);
if (bytes && bytes_len)
{
if ((int) bytes[0] == 4)
::write (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor(), "quit()", 6);
else
::write (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor(), bytes, bytes_len);
}
::write (script_interpreter->m_embedded_python_pty.GetMasterFileDescriptor(), "\n", 1);
}
else
{
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, GotToken, bytes='%s', byte_len = %d, Master File Descriptor is bad.",
bytes,
bytes_len);
reader.SetIsDone (true);
}
break;
case eInputReaderDone:
script_interpreter->LeaveSession ();
// Restore terminal settings if they were validly saved
if (log)
log->Printf ("ScriptInterpreterPython::InputReaderCallback, Done, closing down input reader.");
script_interpreter->RestoreTerminalState ();
script_interpreter->m_embedded_python_pty.CloseMasterFileDescriptor();
break;
}
return bytes_len;
}
void
ScriptInterpreterPython::ExecuteInterpreterLoop ()
{
Timer scoped_timer (__PRETTY_FUNCTION__, __PRETTY_FUNCTION__);
Debugger &debugger = GetCommandInterpreter().GetDebugger();
// At the moment, the only time the debugger does not have an input file handle is when this is called
// directly from Python, in which case it is both dangerous and unnecessary (not to mention confusing) to
// try to embed a running interpreter loop inside the already running Python interpreter loop, so we won't
// do it.
if (!debugger.GetInputFile().IsValid())
return;
InputReaderSP reader_sp (new InputReader(debugger));
if (reader_sp)
{
Error error (reader_sp->Initialize (ScriptInterpreterPython::InputReaderCallback,
this, // baton
eInputReaderGranularityLine, // token size, to pass to callback function
NULL, // end token
NULL, // prompt
true)); // echo input
if (error.Success())
{
debugger.PushInputReader (reader_sp);
m_embedded_thread_input_reader_sp = reader_sp;
}
}
}
bool
ScriptInterpreterPython::ExecuteOneLineWithReturn (const char *in_string,
ScriptInterpreter::ReturnType return_type,
void *ret_value)
{
bool need_to_release_lock = true;
if (CurrentThreadHasPythonLock())
need_to_release_lock = false;
else if (!GetPythonLock (1))
{
fprintf ((m_dbg_stdout ? m_dbg_stdout : stdout),
"Python interpreter is currently locked by another thread; unable to process command.\n");
return false;
}
EnterSession ();
PyObject *py_return = NULL;
PyObject *mainmod = PyImport_AddModule ("__main__");
PyObject *globals = PyModule_GetDict (mainmod);
PyObject *locals = NULL;
PyObject *py_error = NULL;
bool ret_success = false;
bool should_decrement_locals = false;
int success;
if (PyDict_Check (globals))
{
PyObject *key, *value;
Py_ssize_t pos = 0;
int i = 0;
while (PyDict_Next (globals, &pos, &key, &value))
{
// We have stolen references to the key and value objects in the dictionary; we need to increment them now
// so that Python's garbage collector doesn't collect them out from under us.
Py_INCREF (key);
Py_INCREF (value);
char *c_str = PyString_AsString (key);
if (strcmp (c_str, m_dictionary_name.c_str()) == 0)
locals = value;
++i;
}
}
if (locals == NULL)
{
locals = PyObject_GetAttrString (globals, m_dictionary_name.c_str());
should_decrement_locals = true;
}
if (locals == NULL)
{
locals = globals;
should_decrement_locals = false;
}
py_error = PyErr_Occurred();
if (py_error != NULL)
PyErr_Clear();
if (in_string != NULL)
{
py_return = PyRun_String (in_string, Py_eval_input, globals, locals);
if (py_return == NULL)
{
py_error = PyErr_Occurred ();
if (py_error != NULL)
PyErr_Clear ();
py_return = PyRun_String (in_string, Py_single_input, globals, locals);
}
if (locals != NULL
&& should_decrement_locals)
Py_DECREF (locals);
if (py_return != NULL)
{
switch (return_type)
{
case eCharPtr: // "char *"
{
const char format[3] = "s#";
success = PyArg_Parse (py_return, format, (char **) &ret_value);
break;
}
case eBool:
{
const char format[2] = "b";
success = PyArg_Parse (py_return, format, (bool *) ret_value);
break;
}
case eShortInt:
{
const char format[2] = "h";
success = PyArg_Parse (py_return, format, (short *) ret_value);
break;
}
case eShortIntUnsigned:
{
const char format[2] = "H";
success = PyArg_Parse (py_return, format, (unsigned short *) ret_value);
break;
}
case eInt:
{
const char format[2] = "i";
success = PyArg_Parse (py_return, format, (int *) ret_value);
break;
}
case eIntUnsigned:
{
const char format[2] = "I";
success = PyArg_Parse (py_return, format, (unsigned int *) ret_value);
break;
}
case eLongInt:
{
const char format[2] = "l";
success = PyArg_Parse (py_return, format, (long *) ret_value);
break;
}
case eLongIntUnsigned:
{
const char format[2] = "k";
success = PyArg_Parse (py_return, format, (unsigned long *) ret_value);
break;
}
case eLongLong:
{
const char format[2] = "L";
success = PyArg_Parse (py_return, format, (long long *) ret_value);
break;
}
case eLongLongUnsigned:
{
const char format[2] = "K";
success = PyArg_Parse (py_return, format, (unsigned long long *) ret_value);
break;
}
case eFloat:
{
const char format[2] = "f";
success = PyArg_Parse (py_return, format, (float *) ret_value);
break;
}
case eDouble:
{
const char format[2] = "d";
success = PyArg_Parse (py_return, format, (double *) ret_value);
break;
}
case eChar:
{
const char format[2] = "c";
success = PyArg_Parse (py_return, format, (char *) ret_value);
break;
}
default:
{}
}
Py_DECREF (py_return);
if (success)
ret_success = true;
else
ret_success = false;
}
}
py_error = PyErr_Occurred();
if (py_error != NULL)
{
if (PyErr_GivenExceptionMatches (py_error, PyExc_SyntaxError))
PyErr_Print ();
PyErr_Clear();
ret_success = false;
}
LeaveSession ();
if (need_to_release_lock)
ReleasePythonLock();
return ret_success;
}
bool
ScriptInterpreterPython::ExecuteMultipleLines (const char *in_string)
{
FILE *tmp_fh = (m_dbg_stdout ? m_dbg_stdout : stdout);
bool need_to_release_lock = true;
if (CurrentThreadHasPythonLock())
need_to_release_lock = false;
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh, "Python interpreter locked on another thread; waiting to acquire lock...\n");
}
EnterSession ();
bool success = false;
PyObject *py_return = NULL;
PyObject *mainmod = PyImport_AddModule ("__main__");
PyObject *globals = PyModule_GetDict (mainmod);
PyObject *locals = NULL;
PyObject *py_error = NULL;
bool should_decrement_locals = false;
if (PyDict_Check (globals))
{
PyObject *key, *value;
Py_ssize_t pos = 0;
while (PyDict_Next (globals, &pos, &key, &value))
{
// We have stolen references to the key and value objects in the dictionary; we need to increment them now
// so that Python's garbage collector doesn't collect them out from under us.
Py_INCREF (key);
Py_INCREF (value);
if (strcmp (PyString_AsString (key), m_dictionary_name.c_str()) == 0)
locals = value;
}
}
if (locals == NULL)
{
locals = PyObject_GetAttrString (globals, m_dictionary_name.c_str());
should_decrement_locals = true;
}
if (locals == NULL)
{
locals = globals;
should_decrement_locals = false;
}
py_error = PyErr_Occurred();
if (py_error != NULL)
PyErr_Clear();
if (in_string != NULL)
{
struct _node *compiled_node = PyParser_SimpleParseString (in_string, Py_file_input);
if (compiled_node)
{
PyCodeObject *compiled_code = PyNode_Compile (compiled_node, "temp.py");
if (compiled_code)
{
py_return = PyEval_EvalCode (compiled_code, globals, locals);
if (py_return != NULL)
{
success = true;
Py_DECREF (py_return);
}
if (locals && should_decrement_locals)
Py_DECREF (locals);
}
}
}
py_error = PyErr_Occurred ();
if (py_error != NULL)
{
if (PyErr_GivenExceptionMatches (py_error, PyExc_SyntaxError))
PyErr_Print ();
PyErr_Clear();
success = false;
}
LeaveSession ();
if (need_to_release_lock)
ReleasePythonLock();
return success;
}
static const char *g_reader_instructions = "Enter your Python command(s). Type 'DONE' to end.";
size_t
ScriptInterpreterPython::GenerateBreakpointOptionsCommandCallback
(
void *baton,
InputReader &reader,
InputReaderAction notification,
const char *bytes,
size_t bytes_len
)
{
static StringList commands_in_progress;
StreamSP out_stream = reader.GetDebugger().GetAsyncOutputStream();
bool batch_mode = reader.GetDebugger().GetCommandInterpreter().GetBatchCommandMode();
switch (notification)
{
case eInputReaderActivate:
{
commands_in_progress.Clear();
if (!batch_mode)
{
out_stream->Printf ("%s\n", g_reader_instructions);
if (reader.GetPrompt())
out_stream->Printf ("%s", reader.GetPrompt());
out_stream->Flush ();
}
}
break;
case eInputReaderDeactivate:
break;
case eInputReaderReactivate:
if (reader.GetPrompt() && !batch_mode)
{
out_stream->Printf ("%s", reader.GetPrompt());
out_stream->Flush ();
}
break;
case eInputReaderAsynchronousOutputWritten:
break;
case eInputReaderGotToken:
{
std::string temp_string (bytes, bytes_len);
commands_in_progress.AppendString (temp_string.c_str());
if (!reader.IsDone() && reader.GetPrompt() && !batch_mode)
{
out_stream->Printf ("%s", reader.GetPrompt());
out_stream->Flush ();
}
}
break;
case eInputReaderEndOfFile:
case eInputReaderInterrupt:
// Control-c (SIGINT) & control-d both mean finish & exit.
reader.SetIsDone(true);
// Control-c (SIGINT) ALSO means cancel; do NOT create a breakpoint command.
if (notification == eInputReaderInterrupt)
commands_in_progress.Clear();
// Fall through here...
case eInputReaderDone:
{
BreakpointOptions *bp_options = (BreakpointOptions *)baton;
std::auto_ptr<BreakpointOptions::CommandData> data_ap(new BreakpointOptions::CommandData());
data_ap->user_source.AppendList (commands_in_progress);
if (data_ap.get())
{
ScriptInterpreter *interpreter = reader.GetDebugger().GetCommandInterpreter().GetScriptInterpreter();
if (interpreter)
{
if (interpreter->GenerateBreakpointCommandCallbackData (data_ap->user_source,
data_ap->script_source))
{
if (data_ap->script_source.GetSize() == 1)
{
BatonSP baton_sp (new BreakpointOptions::CommandBaton (data_ap.release()));
bp_options->SetCallback (ScriptInterpreterPython::BreakpointCallbackFunction, baton_sp);
}
}
else if (!batch_mode)
{
out_stream->Printf ("Warning: No command attached to breakpoint.\n");
out_stream->Flush();
}
}
else
{
if (!batch_mode)
{
out_stream->Printf ("Warning: Unable to find script intepreter; no command attached to breakpoint.\n");
out_stream->Flush();
}
}
}
}
break;
}
return bytes_len;
}
void
ScriptInterpreterPython::CollectDataForBreakpointCommandCallback (BreakpointOptions *bp_options,
CommandReturnObject &result)
{
Debugger &debugger = GetCommandInterpreter().GetDebugger();
InputReaderSP reader_sp (new InputReader (debugger));
if (reader_sp)
{
Error err = reader_sp->Initialize (
ScriptInterpreterPython::GenerateBreakpointOptionsCommandCallback,
bp_options, // baton
eInputReaderGranularityLine, // token size, for feeding data to callback function
"DONE", // end token
"> ", // prompt
true); // echo input
if (err.Success())
debugger.PushInputReader (reader_sp);
else
{
result.AppendError (err.AsCString());
result.SetStatus (eReturnStatusFailed);
}
}
else
{
result.AppendError("out of memory");
result.SetStatus (eReturnStatusFailed);
}
}
// Set a Python one-liner as the callback for the breakpoint.
void
ScriptInterpreterPython::SetBreakpointCommandCallback (BreakpointOptions *bp_options,
const char *oneliner)
{
std::auto_ptr<BreakpointOptions::CommandData> data_ap(new BreakpointOptions::CommandData());
// It's necessary to set both user_source and script_source to the oneliner.
// The former is used to generate callback description (as in breakpoint command list)
// while the latter is used for Python to interpret during the actual callback.
data_ap->user_source.AppendString (oneliner);
if (GenerateBreakpointCommandCallbackData (data_ap->user_source, data_ap->script_source))
{
if (data_ap->script_source.GetSize() == 1)
{
BatonSP baton_sp (new BreakpointOptions::CommandBaton (data_ap.release()));
bp_options->SetCallback (ScriptInterpreterPython::BreakpointCallbackFunction, baton_sp);
}
}
return;
}
bool
ScriptInterpreterPython::ExportFunctionDefinitionToInterpreter (StringList &function_def)
{
// Convert StringList to one long, newline delimited, const char *.
std::string function_def_string;
int num_lines = function_def.GetSize();
for (int i = 0; i < num_lines; ++i)
{
function_def_string.append (function_def.GetStringAtIndex(i));
if (function_def_string.at (function_def_string.length() - 1) != '\n')
function_def_string.append ("\n");
}
return ExecuteMultipleLines (function_def_string.c_str());
}
// TODO move both GenerateTypeScriptFunction and GenerateBreakpointCommandCallbackData to actually
// use this code to generate their functions
bool
ScriptInterpreterPython::GenerateFunction(std::string& signature, StringList &input, StringList &output)
{
int num_lines = input.GetSize ();
if (num_lines == 0)
return false;
StreamString sstr;
StringList auto_generated_function;
auto_generated_function.AppendString (signature.c_str());
auto_generated_function.AppendString (" global_dict = globals()"); // Grab the global dictionary
auto_generated_function.AppendString (" new_keys = dict.keys()"); // Make a list of keys in the session dict
auto_generated_function.AppendString (" old_keys = global_dict.keys()"); // Save list of keys in global dict
auto_generated_function.AppendString (" global_dict.update (dict)"); // Add the session dictionary to the
// global dictionary.
// Wrap everything up inside the function, increasing the indentation.
for (int i = 0; i < num_lines; ++i)
{
sstr.Clear ();
sstr.Printf (" %s", input.GetStringAtIndex (i));
auto_generated_function.AppendString (sstr.GetData());
}
auto_generated_function.AppendString (" for key in new_keys:"); // Iterate over all the keys from session dict
auto_generated_function.AppendString (" dict[key] = global_dict[key]"); // Update session dict values
auto_generated_function.AppendString (" if key not in old_keys:"); // If key was not originally in global dict
auto_generated_function.AppendString (" del global_dict[key]"); // ...then remove key/value from global dict
// Verify that the results are valid Python.
if (!ExportFunctionDefinitionToInterpreter (auto_generated_function))
return false;
return true;
}
// this implementation is identical to GenerateBreakpointCommandCallbackData (apart from the name
// given to generated functions, of course)
bool
ScriptInterpreterPython::GenerateTypeScriptFunction (StringList &user_input, StringList &output)
{
static int num_created_functions = 0;
user_input.RemoveBlankLines ();
int num_lines = user_input.GetSize ();
StreamString sstr;
// Check to see if we have any data; if not, just return.
if (user_input.GetSize() == 0)
return false;
// Take what the user wrote, wrap it all up inside one big auto-generated Python function, passing in the
// ValueObject as parameter to the function.
sstr.Printf ("lldb_autogen_python_type_print_func_%d", num_created_functions);
++num_created_functions;
std::string auto_generated_function_name = sstr.GetData();
sstr.Clear();
StringList auto_generated_function;
// Create the function name & definition string.
sstr.Printf ("def %s (valobj, dict):", auto_generated_function_name.c_str());
auto_generated_function.AppendString (sstr.GetData());
// Pre-pend code for setting up the session dictionary.
auto_generated_function.AppendString (" global_dict = globals()"); // Grab the global dictionary
auto_generated_function.AppendString (" new_keys = dict.keys()"); // Make a list of keys in the session dict
auto_generated_function.AppendString (" old_keys = global_dict.keys()"); // Save list of keys in global dict
auto_generated_function.AppendString (" global_dict.update (dict)"); // Add the session dictionary to the
// global dictionary.
// Wrap everything up inside the function, increasing the indentation.
for (int i = 0; i < num_lines; ++i)
{
sstr.Clear ();
sstr.Printf (" %s", user_input.GetStringAtIndex (i));
auto_generated_function.AppendString (sstr.GetData());
}
// Append code to clean up the global dictionary and update the session dictionary (all updates in the function
// got written to the values in the global dictionary, not the session dictionary).
auto_generated_function.AppendString (" for key in new_keys:"); // Iterate over all the keys from session dict
auto_generated_function.AppendString (" dict[key] = global_dict[key]"); // Update session dict values
auto_generated_function.AppendString (" if key not in old_keys:"); // If key was not originally in global dict
auto_generated_function.AppendString (" del global_dict[key]"); // ...then remove key/value from global dict
// Verify that the results are valid Python.
if (!ExportFunctionDefinitionToInterpreter (auto_generated_function))
return false;
// Store the name of the auto-generated function to be called.
output.AppendString (auto_generated_function_name.c_str());
return true;
}
bool
ScriptInterpreterPython::GenerateTypeSynthClass (StringList &user_input, StringList &output)
{
static int num_created_classes = 0;
user_input.RemoveBlankLines ();
int num_lines = user_input.GetSize ();
StreamString sstr;
// Check to see if we have any data; if not, just return.
if (user_input.GetSize() == 0)
return false;
// Wrap all user input into a Python class
sstr.Printf ("lldb_autogen_python_type_synth_class_%d", num_created_classes);
++num_created_classes;
std::string auto_generated_class_name = sstr.GetData();
sstr.Clear();
StringList auto_generated_class;
// Create the function name & definition string.
sstr.Printf ("class %s:", auto_generated_class_name.c_str());
auto_generated_class.AppendString (sstr.GetData());
// Wrap everything up inside the class, increasing the indentation.
for (int i = 0; i < num_lines; ++i)
{
sstr.Clear ();
sstr.Printf (" %s", user_input.GetStringAtIndex (i));
auto_generated_class.AppendString (sstr.GetData());
}
// Verify that the results are valid Python.
// (even though the method is ExportFunctionDefinitionToInterpreter, a class will actually be exported)
// (TODO: rename that method to ExportDefinitionToInterpreter)
if (!ExportFunctionDefinitionToInterpreter (auto_generated_class))
return false;
// Store the name of the auto-generated class
output.AppendString (auto_generated_class_name.c_str());
return true;
}
void*
ScriptInterpreterPython::CreateSyntheticScriptedProvider (std::string class_name,
lldb::ValueObjectSP valobj)
{
if (class_name.empty())
return NULL;
if (!valobj.get())
return NULL;
Target *target = valobj->GetUpdatePoint().GetTargetSP().get();
if (!target)
return NULL;
Debugger &debugger = target->GetDebugger();
ScriptInterpreter *script_interpreter = debugger.GetCommandInterpreter().GetScriptInterpreter();
ScriptInterpreterPython *python_interpreter = (ScriptInterpreterPython *) script_interpreter;
if (!script_interpreter)
return NULL;
void* ret_val;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_synthetic_script (class_name,
python_interpreter->m_dictionary_name.c_str(),
valobj);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_synthetic_script (class_name,
python_interpreter->m_dictionary_name.c_str(),
valobj);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
bool
ScriptInterpreterPython::GenerateTypeScriptFunction (const char* oneliner, StringList &output)
{
StringList input(oneliner);
return GenerateTypeScriptFunction(input, output);
}
bool
ScriptInterpreterPython::GenerateBreakpointCommandCallbackData (StringList &user_input, StringList &callback_data)
{
static int num_created_functions = 0;
user_input.RemoveBlankLines ();
int num_lines = user_input.GetSize ();
StreamString sstr;
// Check to see if we have any data; if not, just return.
if (user_input.GetSize() == 0)
return false;
// Take what the user wrote, wrap it all up inside one big auto-generated Python function, passing in the
// frame and breakpoint location as parameters to the function.
sstr.Printf ("lldb_autogen_python_bp_callback_func_%d", num_created_functions);
++num_created_functions;
std::string auto_generated_function_name = sstr.GetData();
sstr.Clear();
StringList auto_generated_function;
// Create the function name & definition string.
sstr.Printf ("def %s (frame, bp_loc, dict):", auto_generated_function_name.c_str());
auto_generated_function.AppendString (sstr.GetData());
// Pre-pend code for setting up the session dictionary.
auto_generated_function.AppendString (" global_dict = globals()"); // Grab the global dictionary
auto_generated_function.AppendString (" new_keys = dict.keys()"); // Make a list of keys in the session dict
auto_generated_function.AppendString (" old_keys = global_dict.keys()"); // Save list of keys in global dict
auto_generated_function.AppendString (" global_dict.update (dict)"); // Add the session dictionary to the
// global dictionary.
// Wrap everything up inside the function, increasing the indentation.
for (int i = 0; i < num_lines; ++i)
{
sstr.Clear ();
sstr.Printf (" %s", user_input.GetStringAtIndex (i));
auto_generated_function.AppendString (sstr.GetData());
}
// Append code to clean up the global dictionary and update the session dictionary (all updates in the function
// got written to the values in the global dictionary, not the session dictionary).
auto_generated_function.AppendString (" for key in new_keys:"); // Iterate over all the keys from session dict
auto_generated_function.AppendString (" dict[key] = global_dict[key]"); // Update session dict values
auto_generated_function.AppendString (" if key not in old_keys:"); // If key was not originally in global dict
auto_generated_function.AppendString (" del global_dict[key]"); // ...then remove key/value from global dict
// Verify that the results are valid Python.
if (!ExportFunctionDefinitionToInterpreter (auto_generated_function))
{
return false;
}
// Store the name of the auto-generated function to be called.
callback_data.AppendString (auto_generated_function_name.c_str());
return true;
}
std::string
ScriptInterpreterPython::CallPythonScriptFunction (const char *python_function_name,
lldb::ValueObjectSP valobj)
{
if (!python_function_name || !(*python_function_name))
return "<no function>";
if (!valobj.get())
return "<no object>";
Target *target = valobj->GetUpdatePoint().GetTargetSP().get();
if (!target)
return "<no target>";
Debugger &debugger = target->GetDebugger();
ScriptInterpreter *script_interpreter = debugger.GetCommandInterpreter().GetScriptInterpreter();
ScriptInterpreterPython *python_interpreter = (ScriptInterpreterPython *) script_interpreter;
if (!script_interpreter)
return "<no python>";
std::string ret_val;
if (python_function_name
&& *python_function_name)
{
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_typescript_callback (python_function_name,
python_interpreter->m_dictionary_name.c_str(),
valobj);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_typescript_callback (python_function_name,
python_interpreter->m_dictionary_name.c_str(),
valobj);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
}
else
return "<no function name>";
return ret_val;
}
bool
ScriptInterpreterPython::BreakpointCallbackFunction
(
void *baton,
StoppointCallbackContext *context,
user_id_t break_id,
user_id_t break_loc_id
)
{
BreakpointOptions::CommandData *bp_option_data = (BreakpointOptions::CommandData *) baton;
const char *python_function_name = bp_option_data->script_source.GetStringAtIndex (0);
if (!context)
return true;
Target *target = context->exe_ctx.target;
if (!target)
return true;
Debugger &debugger = target->GetDebugger();
ScriptInterpreter *script_interpreter = debugger.GetCommandInterpreter().GetScriptInterpreter();
ScriptInterpreterPython *python_interpreter = (ScriptInterpreterPython *) script_interpreter;
if (!script_interpreter)
return true;
if (python_function_name != NULL
&& python_function_name[0] != '\0')
{
Thread *thread = context->exe_ctx.thread;
const StackFrameSP stop_frame_sp (thread->GetStackFrameSPForStackFramePtr (context->exe_ctx.frame));
BreakpointSP breakpoint_sp = target->GetBreakpointByID (break_id);
if (breakpoint_sp)
{
const BreakpointLocationSP bp_loc_sp (breakpoint_sp->FindLocationByID (break_loc_id));
if (stop_frame_sp && bp_loc_sp)
{
bool ret_val = true;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_breakpoint_callback (python_function_name,
python_interpreter->m_dictionary_name.c_str(),
stop_frame_sp,
bp_loc_sp);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_breakpoint_callback (python_function_name,
python_interpreter->m_dictionary_name.c_str(),
stop_frame_sp,
bp_loc_sp);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
}
}
// We currently always true so we stop in case anything goes wrong when
// trying to call the script function
return true;
}
lldb::thread_result_t
ScriptInterpreterPython::RunEmbeddedPythonInterpreter (lldb::thread_arg_t baton)
{
ScriptInterpreterPython *script_interpreter = (ScriptInterpreterPython *) baton;
LogSP log (lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_SCRIPT));
if (log)
log->Printf ("%p ScriptInterpreterPython::RunEmbeddedPythonInterpreter () thread starting...", baton);
char error_str[1024];
const char *pty_slave_name = script_interpreter->m_embedded_python_pty.GetSlaveName (error_str, sizeof (error_str));
bool need_to_release_lock = true;
bool safe_to_run = false;
if (CurrentThreadHasPythonLock())
{
safe_to_run = true;
need_to_release_lock = false;
}
else
{
int interval = 1;
safe_to_run = GetPythonLock (interval);
while (!safe_to_run)
{
interval = interval * 2;
safe_to_run = GetPythonLock (interval);
}
}
if (pty_slave_name != NULL && safe_to_run)
{
StreamString run_string;
script_interpreter->EnterSession ();
run_string.Printf ("run_one_line (%s, 'save_stderr = sys.stderr')", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear ();
run_string.Printf ("run_one_line (%s, 'sys.stderr = sys.stdout')", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear ();
run_string.Printf ("run_one_line (%s, 'save_stdin = sys.stdin')", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear ();
run_string.Printf ("run_one_line (%s, \"sys.stdin = open ('%s', 'r')\")", script_interpreter->m_dictionary_name.c_str(),
pty_slave_name);
PyRun_SimpleString (run_string.GetData());
run_string.Clear ();
// The following call drops into the embedded interpreter loop and stays there until the
// user chooses to exit from the Python interpreter.
// When in the embedded interpreter, the user can call arbitrary system and Python stuff, which may require
// the ability to run multi-threaded stuff, so we need to surround the call to the embedded interpreter with
// calls to Py_BEGIN_ALLOW_THREADS and Py_END_ALLOW_THREADS.
// We ALSO need to surround the call to the embedded interpreter with calls to PyGILState_Ensure and
// PyGILState_Release. This is because this embedded interpreter is being run on a DIFFERENT THREAD than
// the thread on which the call to Py_Initialize (and PyEval_InitThreads) was called. Those initializations
// called PyGILState_Ensure on *that* thread, but it also needs to be called on *this* thread. Otherwise,
// if the user calls Python code that does threading stuff, the interpreter state will be off, and things could
// hang (it's happened before).
Py_BEGIN_ALLOW_THREADS
PyGILState_STATE gstate = PyGILState_Ensure();
run_string.Printf ("run_python_interpreter (%s)", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear ();
PyGILState_Release (gstate);
Py_END_ALLOW_THREADS
run_string.Printf ("run_one_line (%s, 'sys.stdin = save_stdin')", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
run_string.Printf ("run_one_line (%s, 'sys.stderr = save_stderr')", script_interpreter->m_dictionary_name.c_str());
PyRun_SimpleString (run_string.GetData());
run_string.Clear();
script_interpreter->LeaveSession ();
}
if (!safe_to_run)
fprintf ((script_interpreter->m_dbg_stdout ? script_interpreter->m_dbg_stdout : stdout),
"Python interpreter locked on another thread; unable to acquire lock.\n");
if (need_to_release_lock)
ReleasePythonLock ();
if (script_interpreter->m_embedded_thread_input_reader_sp)
script_interpreter->m_embedded_thread_input_reader_sp->SetIsDone (true);
script_interpreter->m_embedded_python_pty.CloseSlaveFileDescriptor();
script_interpreter->m_pty_slave_is_open = false;
log = lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_SCRIPT);
if (log)
log->Printf ("%p ScriptInterpreterPython::RunEmbeddedPythonInterpreter () thread exiting...", baton);
// Clean up the input reader and make the debugger pop it off the stack.
Debugger &debugger = script_interpreter->GetCommandInterpreter().GetDebugger();
const InputReaderSP reader_sp = script_interpreter->m_embedded_thread_input_reader_sp;
script_interpreter->m_embedded_thread_input_reader_sp.reset();
debugger.PopInputReader (reader_sp);
return NULL;
}
uint32_t
ScriptInterpreterPython::CalculateNumChildren (void *implementor)
{
if (!implementor)
return 0;
if (!g_swig_calc_children)
return 0;
ScriptInterpreterPython *python_interpreter = this;
uint32_t ret_val = 0;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_calc_children (implementor);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_calc_children (implementor);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
void*
ScriptInterpreterPython::GetChildAtIndex (void *implementor, uint32_t idx)
{
if (!implementor)
return 0;
if (!g_swig_get_child_index)
return 0;
ScriptInterpreterPython *python_interpreter = this;
void* ret_val = NULL;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_get_child_index (implementor,idx);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_get_child_index (implementor,idx);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
int
ScriptInterpreterPython::GetIndexOfChildWithName (void *implementor, const char* child_name)
{
if (!implementor)
return UINT32_MAX;
if (!g_swig_get_index_child)
return UINT32_MAX;
ScriptInterpreterPython *python_interpreter = this;
int ret_val = UINT32_MAX;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_get_index_child (implementor, child_name);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_get_index_child (implementor, child_name);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
void
ScriptInterpreterPython::UpdateSynthProviderInstance (void* implementor)
{
if (!implementor)
return;
if (!g_swig_update_provider)
return;
ScriptInterpreterPython *python_interpreter = this;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
g_swig_update_provider (implementor);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
g_swig_update_provider (implementor);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return;
}
lldb::SBValue*
ScriptInterpreterPython::CastPyObjectToSBValue (void* data)
{
if (!data)
return NULL;
if (!g_swig_cast_to_sbvalue)
return NULL;
ScriptInterpreterPython *python_interpreter = this;
lldb::SBValue* ret_val = NULL;
FILE *tmp_fh = (python_interpreter->m_dbg_stdout ? python_interpreter->m_dbg_stdout : stdout);
if (CurrentThreadHasPythonLock())
{
python_interpreter->EnterSession ();
ret_val = g_swig_cast_to_sbvalue (data);
python_interpreter->LeaveSession ();
}
else
{
while (!GetPythonLock (1))
fprintf (tmp_fh,
"Python interpreter locked on another thread; waiting to acquire lock...\n");
python_interpreter->EnterSession ();
ret_val = g_swig_cast_to_sbvalue (data);
python_interpreter->LeaveSession ();
ReleasePythonLock ();
}
return ret_val;
}
void
ScriptInterpreterPython::InitializeInterpreter (SWIGInitCallback python_swig_init_callback,
SWIGBreakpointCallbackFunction python_swig_breakpoint_callback,
SWIGPythonTypeScriptCallbackFunction python_swig_typescript_callback,
SWIGPythonCreateSyntheticProvider python_swig_synthetic_script,
SWIGPythonCalculateNumChildren python_swig_calc_children,
SWIGPythonGetChildAtIndex python_swig_get_child_index,
SWIGPythonGetIndexOfChildWithName python_swig_get_index_child,
SWIGPythonCastPyObjectToSBValue python_swig_cast_to_sbvalue,
SWIGPythonUpdateSynthProviderInstance python_swig_update_provider)
{
g_swig_init_callback = python_swig_init_callback;
g_swig_breakpoint_callback = python_swig_breakpoint_callback;
g_swig_typescript_callback = python_swig_typescript_callback;
g_swig_synthetic_script = python_swig_synthetic_script;
g_swig_calc_children = python_swig_calc_children;
g_swig_get_child_index = python_swig_get_child_index;
g_swig_get_index_child = python_swig_get_index_child;
g_swig_cast_to_sbvalue = python_swig_cast_to_sbvalue;
g_swig_update_provider = python_swig_update_provider;
}
void
ScriptInterpreterPython::InitializePrivate ()
{
Timer scoped_timer (__PRETTY_FUNCTION__, __PRETTY_FUNCTION__);
// Python will muck with STDIN terminal state, so save off any current TTY
// settings so we can restore them.
TerminalState stdin_tty_state;
stdin_tty_state.Save(STDIN_FILENO, false);
// Find the module that owns this code and use that path we get to
// set the PYTHONPATH appropriately.
FileSpec file_spec;
char python_dir_path[PATH_MAX];
if (Host::GetLLDBPath (ePathTypePythonDir, file_spec))
{
std::string python_path;
const char *curr_python_path = ::getenv ("PYTHONPATH");
if (curr_python_path)
{
// We have a current value for PYTHONPATH, so lets append to it
python_path.append (curr_python_path);
}
if (file_spec.GetPath(python_dir_path, sizeof (python_dir_path)))
{
if (!python_path.empty())
python_path.append (1, ':');
python_path.append (python_dir_path);
}
if (Host::GetLLDBPath (ePathTypeLLDBShlibDir, file_spec))
{
if (file_spec.GetPath(python_dir_path, sizeof (python_dir_path)))
{
if (!python_path.empty())
python_path.append (1, ':');
python_path.append (python_dir_path);
}
}
const char *pathon_path_env_cstr = python_path.c_str();
::setenv ("PYTHONPATH", pathon_path_env_cstr, 1);
}
PyEval_InitThreads ();
Py_InitializeEx (0);
// Initialize SWIG after setting up python
assert (g_swig_init_callback != NULL);
g_swig_init_callback ();
// Update the path python uses to search for modules to include the current directory.
PyRun_SimpleString ("import sys");
PyRun_SimpleString ("sys.path.append ('.')");
PyRun_SimpleString ("import embedded_interpreter");
PyRun_SimpleString ("from embedded_interpreter import run_python_interpreter");
PyRun_SimpleString ("from embedded_interpreter import run_one_line");
PyRun_SimpleString ("import sys");
PyRun_SimpleString ("from termios import *");
stdin_tty_state.Restore();
}
//void
//ScriptInterpreterPython::Terminate ()
//{
// // We are intentionally NOT calling Py_Finalize here (this would be the logical place to call it). Calling
// // Py_Finalize here causes test suite runs to seg fault: The test suite runs in Python. It registers
// // SBDebugger::Terminate to be called 'at_exit'. When the test suite Python harness finishes up, it calls
// // Py_Finalize, which calls all the 'at_exit' registered functions. SBDebugger::Terminate calls Debugger::Terminate,
// // which calls lldb::Terminate, which calls ScriptInterpreter::Terminate, which calls
// // ScriptInterpreterPython::Terminate. So if we call Py_Finalize here, we end up with Py_Finalize being called from
// // within Py_Finalize, which results in a seg fault.
// //
// // Since this function only gets called when lldb is shutting down and going away anyway, the fact that we don't
// // actually call Py_Finalize should not cause any problems (everything should shut down/go away anyway when the
// // process exits).
// //
//// Py_Finalize ();
//}
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